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Nov 16, 2017 - ABSTRACT: The use of nuclear magnetic resonance chemical shift perturbation to monitor changes taking place around the binding site of ...
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The sign of NMR chemical shift difference as a determinant of the origin of binding selectivity: Elucidation of the positiondependence of phosphorylation in ligands binding to Scribble PDZ1 Gustav Sundell, Beat Vögeli, Ylva Ivarsson, and Celestine Chi Biochemistry, Just Accepted Manuscript • DOI: 10.1021/acs.biochem.7b00965 • Publication Date (Web): 16 Nov 2017 Downloaded from http://pubs.acs.org on November 17, 2017

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Biochemistry

The sign of NMR chemical shift difference as a determinant of the origin of binding selectivity: Elucidation of the position-dependence of phosphorylation in ligands binding to Scribble PDZ1

Gustav N. Sundell1, Beat Vögeli2, Ylva Ivarsson1* and Celestine N. Chi3*

1

Department of Chemistry-BMC, Uppsala University, BMC Box 576, SE-75123 Uppsala,

Sweden 2

Department of Biochemistry and Molecular Genetics, University of Colorado at Denver, 12801

East 17th Avenue, Aurora, CO 80045, USA 3

Department of Medical Biochemistry and Microbiology, Uppsala University, BMC Box 582,

SE-75123 Uppsala, Sweden.

*Corresponding author: E-mail: [email protected] [email protected]

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ABSTRACT The use of NMR chemical shift perturbation to monitor changes taking place around the binding site of a ligand-protein interaction is a routine and widely applied methodology in the field of protein biochemistry. Shifts are often acquired by titrating various concentrations of ligand to a fixed concentration of the receptor and may serve the purposes, amongst others, to determine affinity constants, locate binding surfaces, or differentiate between binding mechanisms. Shifts are quantified by the so-called combined chemical shift difference. Although the directionality of shift changes are often used for detailed analysis of specific cases, the approach has not been adapted in standard chemical shift monitoring. This is surprising as it would not require additional efforts. Here, we demonstrate the importance of the sign of chemical shift difference induced by ligand-protein interaction. We analyze the sign of the

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N/1H shift changes of the

PDZ1 domain of Scribble upon interaction with two pairs of phosphorylated and unphosphorylated peptides. We find that detailed differences in the molecular basis of this PDZligand interaction can be obtained from our analysis to which the classical method of combined chemical shift perturbation analysis is insensitive. In addition, we find a correlation between affinity and millisecond motions. Application of the methodology to Cyclophilin, a cis-trans isomerase reveals molecular details of peptide recognition. We reckon our directionality-vector chemical shift analysis as a method of choice when distinguishing the molecular origin of binding specificities of a class of similar ligands as it is often done in drug discovery.

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INTRODUCTION Detailed understanding of intermolecular interactions requires highly localized probes. Monitoring changes of NMR chemical shifts of proteins upon ligand titration is a common and convenient tool to obtain residue- or even atom-specific information. It is well known that the chemical shift is extremely sensitive to the local electronic environment and its changes in magnitude as well as directionality can be used to infer structural and dynamic rearrangement1, 2. For example, if two ligands repopulate two states of a free protein in opposite ways, the chemical shift changes will also be of opposite directions, because the observed chemical shift is the population-weighted average of the values for the two individual states. This can be seen with two ligands of Pin1, fragments from Cdc25 and FFpSPR, that have opposite effects on the affinity in the catalytic site, and thus exhibit shifts in the opposite directions3, 4. Surprisingly, the standard procedure of chemical shift monitoring involves plotting of a combined function of absolute value change of backbone 1H and 15N shifts 1: ∆CS = SQRT ((∆1H)2 + (X(∆15N)2)

(1)

X is a scaling factor that regulates the weights of H and N shifts and is most commonly chosen 1, 0.1 or 0.2. This approach dismisses the sign of both shifts, which carry valuable information. The full information of a combined chemical shift change may be given in a vector in the 2dimensional 1H/15N space, which would retain the magnitude and sign of both shifts. Here, we propose to use this approach for chemical shift mapping, as no additional experimental effort is required as compared to the standard procedure. We present the utility of the approach with the example of the first PDZ(PSD-95/Dlg/ZO-1) domain of Scribble, where relevant differences in binding modes are hidden when using equation 1, but are recuperated when following our proposed approach. In addition, we applied the approach to Cyclophilin a, a cis-trans isomerase in an attempt to capture fine differences between the interaction of the enzyme with a peptide in a cis- or trans- conformation and the wild-type.

PDZ domains are a major class of protein-protein interacting domains present in the post synaptic density of excitatory neurons

5, 6

. They are small, globular protein domains consisting

of between 90-100 amino acids and often occur as tandem repeats. PDZ domains function

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mainly by recognizing short C-terminal peptide motifs although some also recognize internal peptide motifs7,

8, 9

. The interaction with short C-terminal peptides, also known as canonical

PDZ-binding mode, has been well characterized and the last four amino acids of the peptide has been shown to be essential for recognition and the upstream residues contribute to affinity and specificity 10-12. For class I PDZ-peptide interaction, peptide positions 0 and -2 (numbering from the carboxylate C-terminus) have been deemed important determinants for affinity, while other peptide positions play additional roles in selectivity and enhancement of the binding affinity. There are hundreds of known or putative C-terminal peptide ligands present in the cell13, which are typically shared ligands between several PDZ domains. The mechanism through which PDZ domains distinguish between respective partners is not entirely clear. It is anticipated that phosphorylation of a particular ligand can trigger alternative signaling pathways quite different from the unphosphorylated ligands through disruption or promotion of specific interactions. For example, the Tiam1 PDZ domain binds both phosphorylated and unphosphorylated syndecan 1 as well as phosphorylated syndecan 3 ligands but not other isoforms of syndecans

14

.

Phosphorylation of syndecan 1 promotes cell adhesion and ectodomain cleavage by disrupting the interaction between synthenin PDZ1 and phosphorylated syndecan 1

15, 16

. In summary,

phosphorylation of PDZ ligands has been proposed as a regulatory mechanism17,

18, 14, 20

. A

priority in the PDZ biology is to understand how a single PDZ domain can distinguish between all potential ligands. We recently found that Scribble PDZ1 domain can interact with unphosphorylated and phosphorylated ligands representing the C-termini of different biological proteins. Depending on the phosphorylation site, phosphorylation may have a switching function, increasing the affinity for Scribble PDZ1 and decreasing the affinity for other PDZ domains such as Shank1 PDZ19. Although we probed the molecular mechanism of interaction through NMR structure determination, with hindsight we realized that, the sign shift analysis provides an alternative and feasible approach for gaining deeper understanding of the molecular details of the interactions. Here, we analyze the origin of the binding specificities by probing the directionality of chemical shift perturbation with heteronuclear single quantum coherence spectra as well as slow millisecond dynamics.

RESULTS and DISCUSSION

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Scribble

PDZ1 domain has been shown to selectively bind to the C-terminal peptides of

RPS6KA2 (MKRLTSTRL)19 and colorectal mutant cancer protein (MCC) (RPHTNETSL)20, and that the interactions are tuned in a Ser phosphorylation dependent manner19. In this study, we investigate the molecular origin of these differences by analyzing chemical shifts perturbation from heteronuclear single quantum coherence spectra as well as slow millisecond dynamics probed by NMR transverse relaxation rates (R2). The following peptides were used for the analysis: the unphosphorylated ligands MKRLTSTRL (RPS6KA2) and RPHTNETSL (MCC) and their MKRLTpSTRL and RPHTNET(p)SL being their phosphorylated variants, respectively. The two phosphorylated ligands are probes for the phosphorylation sites at p-3 and p-1, thus allowing the study of phosphorylation in a position-dependent context. The peptides were chosen as their position dependent phosphorylation seemed to play a biological role as switches for different PDZ domains19, 21 .

The sign rather than the magnitude of NMR chemical shift distinguishes the origin of binding affinity In the context of protein-ligand interaction, combined chemical shifts from NMR 1H/15N correlation experiments are routinely used to monitor ligand interaction and ligand binding sites on proteins and receptors in solution. While the approach through which these shifts are interpreted is very powerful in localizing residues undergoing structural changes taking place upon ligand addition, it often fails to dissect the fine details associated with the binding reaction. In contrast, the directionality of the chemical shifts, which is rarely taken into consideration in this analysis, can play a vital role in distinguishing binding mechanisms, for example when two slightly different ligands that interact with the same receptor. The peptides MKRLTSTRL and MKRLTpSTRL, which differ at a single phosphorylation site, both bind to PDZ1 from Scribble but the phosphorylated variant has a higher affinity (KD of 18 versus 4 µΜ from ITC)

19

. We

reanalyzed HSQC experiments performed for free and bound Scribble PDZ1 with peptides phosphorylated at p-1, p-3 as well as unphosphorylated peptides. The shifts were then analyzed as described in the method section. The residue specific assignment is found in supplementary table 1. HSQC spectra tracing chemical shift changes of PDZ1 bound with either of the peptides show that similar residues are affected nearly to the same extent (Figure 1).

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Figure 1. Heteronuclear single quantum coherence (HSQC)

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N-1H spectrum of free and bound PDZ1. (A)

Overlay of PDZ1 free (red), bound to unphosphorylated (green) and phosphorylated MKRLTSTRL peptide (blue). Expansions on specific regions are shown on the top-right hand corner (B) Residues exhibiting shifts of opposite sign are colored in red on a cartoon representation of PDZ1 (pdb: 6ESP). For simplicity, the residue numbers are not shown.

This is explicitly shown in Figure 2A, where the combined chemical shifts from both complexes are plotted. However, this representation does not explain the origin of the difference in binding affinity between the two peptides. In order to identify the origin of these differences we monitor

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the changes of the chemical shifts in a sign-sensitive manner taking into consideration the sign of the shift. Plots of the differences (from the free protein) in 15N shift (∆N) of the Scribble PDZ1 domain bound to the phosphorylated and unphosphorylated peptides are shown in Figure 2B). A shift difference was qualified as significant if its value was above the mean (different from the mean-shift).

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Figure 2. Combined chemical shift difference and sign-sensitive chemical shift difference plots. (A, B) 15N-1H combined chemical shift difference between free Scribble PDZ1 and PDZ1 bound to respective peptides. (C, D) Sign-sensitive

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N chemical shift difference for respective peptides. (E, F) Sign-sensitive 1H chemical shift

difference for respective peptides. The combined chemical shift difference depends only on absolute values; thus, the directionality of the shift is not taken into consideration. On the other hand, the sign-sensitive chemical shift difference plot takes into consideration the directionality of shift changes. Residues contributing differently to binding may be identified.

The majority of the residues move in the same direction, while a few shifted in the opposite direction (Figures 1 and 2). Those residues that experience a difference in the 15N shift include 723, 724, 733, 741-744, 747, 762, 764-765, 774, 795 and 813-814, and color coded on the structure (PDB: 6ESP) (Figure 1B)(for simplicity, the numbers are not shown on the structure). These residues are distributed throughout the PDZ domain, indicating some long-range effect. It is interesting to note that residues 741-744 in the β2 strand that flanks the peptide binding groove seem to respond differently to binding of the p-3 phosphorylated peptide and unphosphorylated peptide ligands. These results are in agreement with our mutational analysis of R762 to alanine, where the R762A mutant showed a decrease in affinity for the p-3 phosphorylated peptide compared to the unphosphorylated peptide19. This further indicates that our analysis can identify subtle differences important for PDZ affinity. Given that the binding data for the p-1 peptide indicates only a minor affinity difference between the unphosphorylated peptide (2.6 µM vs 4.4 µM), we next verified that our analysis could also capture this. Indeed, the combined shift plots are very similar for the p-1 phosphorylated and unphosphorylated peptides (Figures 2C and D). The results indicate that perhaps both peptides interact with PDZ1 using similar residues (Figure. 2D) and phosphorylation at p-1 might not be an important switching site for Scribble PDZ1. The analysis carried out so far is based on differences in the 15N direction. We observe similar trends for 1H (Figure. 2E and F). This is further demonstrated by plotting a two-dimensional vector representation, where the change in the 15N shift is plotted on the abscissa and the change in 1H shift on the ordinate, respectively (Figure. 3).

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Figure 3. Two-dimensional vector representation of 15N and 1H chemical shift change. To properly display the importance of using the sign of the shift change, we plotted the difference between the shift from the free protein and the one when bound to the respective peptides. The change in 15N and 1H shifts is plotted on the abscissa and ordinate, respectively. The plots in (A) and (B) are for the phosphorylated peptide p-3 (orange) and its unphosphorylated variant (blue) respectively, while (C) and (D) are for the phosphorylated peptide p-1 (orange) and its unphosphorylated counter-part (blue), respectively. The labeling of the subset of points shown in (B) reveals that phosphorylation at p-3 causes shift changes that are different from the unphosphorylated variant. Such a pattern is not seen when the peptide phosphorylated at p-1.

In this representation, both the magnitude and the sign of the shift changes are retained making interpretation easy. For the p-3 case, we observe a clear spatial separation of residues (mentioned above) responsible for binding to the phosphorylated and unphosphorylated peptide (Figure 3B). Absence of a strong correlation between 1H and 15N shifts indicates that the binding mechanisms of phosphorylated and unphosphorylated peptides do not differ by simple population shifts in

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opposite directions. There was no spatial separation for peptides p-1 and its unphosphorylated variant, further indicating that both peptides interact with the PDZ domain using similar residues in the same way (Figure 3D). Overall, these findings indicate that the sign of each shift carries more information for distinction of the peptide binding modes than the conventional combined representation. To test if our analysis can capture selectivity differences in other systems, we re-analyzed chemical binding data from Cyclophilin a/peptide interaction that we previously analyzed by the combined chemical shift approach 22 (Figure S1). Cyclophilin a is an enzyme that catalyzes cistrans isomerization of X-proline peptide bonds, where X refers to any amino acid23. We plotted and compared the sign difference plots for Cyclophilin bound to wild-type peptide (the wild type peptide exists in equilibrium mixture between the cis- and trans-isoforms), the cis- and the translocked peptide. While there was virtually no detectable difference between the sign difference plot of Cyclophilin-wild-type peptide complex and Cyclophilin-trans peptide complex (Figure S1 A and B), this was not the case for Cyclophilin-wild-type peptide complex and Cyclophilin-cis peptide complex (Figure S1 C and D). We observed a clear difference in shifts for residues I57, Q63, L90 and K126. As a consequence, comparison of the shift difference between the Cyclophilin-trans peptide complex and Cyclophilin-cis peptide complex showed differences for similar residues (Figure S1 e and f). In addition, we also observed that M100 has a significant sign difference between Cyclophilin bound to the cis peptide and Cyclophilin bound to the trans peptide. It seems likely that these residues that only change their shift in the Cyclophilin-cis peptide complex are responsible for cis-peptide specific recognition. It is important to note that chemical shifts are very sensitive to changes in their surroundings. Thus, the shift change of a particular residue might as well be due to an event experienced by a neighboring residue. What is the role of the residues detected in this analysis in binding and catalysis of Cyclophilin a? I57 (or its neighbor R55 and I56), Q63 and K126 (or its neighbor H125) are active site residues responsible for binding and catalysis. M100 (its neighbor S99) and L90 have all been implicated in conformational change induced by slow millisecond motion24. The fact that all the residues identified in our analysis have been shown to be important for function implies our analysis can capture important molecular determinants for binding selectivity in Cyclophilin.

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Millisecond dynamics in PDZ1 is responsible for the higher affinity of Scribble PDZ1 for the p-3 phosphorylated ligand Having observed that the p-3 position phosphorylated peptide has a higher affinity than the unphosphorylated peptide and that the sign of the chemical shift can be used to explain the origin of this higher affinity, we wondered if the higher affinity is associated or can be explained by the presence of slow exchange processes between the ligand and protein (free and bound). Such dynamics associated with protein-ligand interaction typically takes place on the micromillisecond timescales and thus can be probed by NMR relaxation dispersion 25. These exchange processes cause additional line broadening of the respective NMR spectral resonances and result in exchange contributions to transverse relaxation, Rex = R2 - R2,0, where R2 and R2,0 are the transverse relaxation rates in the presence and absence of exchange, respectively. Rex values depend on the relative populations of the exchanging states, the chemical shift difference (δω) between them and the rates of exchange (kex) 26. We measured and compared backbone R2 rates for free and bound protein with the different peptides. In addition, we deduced R2,0 rates when contributions from exchange processes slower than 80 µs are quenched by application of a 2 kHz spin-lock during measurement of longitudinal relaxation in the rotating frame (R1ρ) (Figure 4). A plot of R2 from Scribble PDZ1 bound to the different peptides shows an increase in millisecond motion when bound to the peptide phosphorylated at -3 position and no change in such motion in the complex with the other peptides (Figure 4).

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Figure 4. NMR

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N transverse spin relaxation measurements. (A, B) Transverse R2 rates for Scribble PDZ1

bound to the phosphopeptides (blue) and unphosphopeptides (red). A protein undergoing micro- to millisecond motion often displays increased R2 rates. These contributions from conformational exchange are quenched if spinlattice relaxation rates are determined in the presence of a spin lock field (R1ρ). Here, we compare the R2 and R1ρ rates for the PDZ1 bound to the peptides p-3, p-1 phosphorylated peptides and their unphosphorylated variants. (A) and b) are R2 rates and R1ρ rates for Scribble PDZ1 bound to the p-3 phosphorylated peptides (blue) and the unphosphorylated variant (red), respectively. C) and d) similar to (A) and (B) but for p-1 phosphorylated peptide and its unphosphorylated counter-part. R1ρ rates were measured with a spinlock field strength of 2 kHz. Nearly all exchange contributions disappear with R1ρ rates indicating that all exchange processes must be slower than 80 µs.

Application of the spin lock pulse reduces the R2 rates to those of the free protein, indicating that these exchange processes must be slower than 80 µs.

CONCLUSION Chemical shifts from protein-ligand binding experiments are often analyzed in an absolute value manner resulting in the loss of an important property of these shifts. Here, we re-introduce the analysis of these shifts taking into consideration their sign. Using this approach, we were able to elucidate the molecular origin of Scribble PDZ1 selectivity. We also observe that the higher affinity (5-fold increase) of PDZ1 for the p-3 phosphorylated peptide correlates with increased millisecond motion as determined from increase in R2 spin-spin relaxation times. Further, we tested the robustness of our method by applying it to the cis-trans isomerase Cyclophilin a. We observed that our approach was able to capture previously identified molecular determinants of binding selectivity and dynamics in this class of enzyme. Our analysis clearly shows that differences in affinities or binding between slightly different ligands interacting with the same protein/enzyme can be predicted by using the sign of the chemical shift.

Acknowledgments: Funding: This work was supported by the Wenner-Gren foundation WG17, returning grants to C. N. C, B. V. was supported by a faculty start-up package at the University of Colorado Denver.

ASSOCIATED COTENT Supporting Information

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1) Materials and method section 2) Supporting Figure 1 3) Supporting table 1

REFERENCES (1) Williamson, M. P. (2013) Using chemical shift perturbation to characterise ligand binding, Prog. Nucl. Magn. Reson. Spectrosc. 73, 1-16. (2) Kohlhoff, K. J., Robustelli, P., Cavalli, A., Salvatella, X., and Vendruscolo, M. (2009) Fast and accurate predictions of protein NMR chemical shifts from interatomic distances, J Am. Chem. So.c 131, 13894-13895. (3) Peng, J. W. (2015) Investigating Dynamic Interdomain Allostery in Pin1, Biophys. Rev. 7, 239-249. (4) Olsson, S., Strotz, D., Vögeli, B., Riek, R., and Cavalli, A. (2016) The Dynamic Basis for Signal Propagation in Human Pin1-WW, Structure 24, 1464-1475. (5) Takeuchi, M., Hata, Y., Hirao, K., Toyoda, A., Irie, M., and Takai, Y. (1997) SAPAPs. A family of PSD-95/SAP90-associated proteins localized at postsynaptic density, J. Biol. Chem. 272, 11943-11951. (6) Nourry, C., Grant, S. G. N., and Borg, J.-P. (2003) PDZ Domain Proteins: Plug and Play!, Sci. STKE 2003, re7-. (7) Hillier, B. J., Christopherson, K. S., Prehoda, K. E., Bredt, D. S., and Lim, W. A. (1999) Unexpected modes of PDZ domain scaffolding revealed by structure of nNOS-syntrophin complex, Science 284, 812-815. (8) Niethammer, M., Valtschanoff, J. G., Kapoor, T. M., Allison, D. W., Weinberg, T. M., Craig, A. M., and Sheng, M. (1998) CRIPT, a novel postsynaptic protein that binds to the third PDZ domain of PSD-95/SAP90, Neuron 20, 693-707. (9) Ivarsson, Y. (2012) Plasticity of PDZ domains in ligand recognition and signaling, FEBS Letters 586, 2638-2647. (10) Bezprozvanny, I., and Maximov, A. (2001) Classification of PDZ domains, FEBS Letters 509, 457-462. (11) Stiffler, M. A., Grantcharova, V. P., Sevecka, M., and MacBeath, G. (2006) Uncovering Quantitative Protein Interaction Networks for Mouse PDZ Domains Using Protein Microarrays, J. Am. Chem. Soc. 128, 5913-5922. (12) Tonikian, R., Zhang, Y., Sazinsky, S. L., Currell, B., Yeh, J. H., Reva, B., Held, H. A., Appleton, B. A., Evangelista, M., Wu, Y., Xin, X., Chan, A. C., Seshagiri, S., Lasky, L. A., Sander, C., Boone, C., Bader, G. D., and Sidhu, S. S. (2008) A specificity map for the PDZ domain family, PLoS Biol. 6, e239. (13) Kim, J., Kim, I., Yang, J. S., Shin, Y. E., Hwang, J., Park, S., Choi, Y. S., and Kim, S. (2012) Rewiring of PDZ domain-ligand interaction network contributed to eukaryotic evolution, PLoS Genet. 8, e1002510.

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(14) Liu, X., Shepherd, T. R., Murray, A. M., Xu, Z., and Fuentes, E. J. (2013) The structure of the Tiam1 PDZ domain/ phospho-syndecan1 complex reveals a ligand conformation that modulates protein dynamics, Structure 21, 342-354. (15) Reiland, J., Ott, V. L., Lebakken, C. S., Yeaman, C., McCarthy, J., and Rapraeger, A. C. (1996) Pervanadate activation of intracellular kinases leads to tyrosine phosphorylation and shedding of syndecan-1, Biochem. J. 319 ( Pt 1), 39-47. (16) Sulka, B., Lortat-Jacob, H., Terreux, R., Letourneur, F., and Rousselle, P. (2009) Tyrosine dephosphorylation of the syndecan-1 PDZ binding domain regulates syntenin-1 recruitment, J. Biol. Chem. 284, 10659-10671. (17) Espejo, A. B., Gao, G., Black, K., Gayatri, S., Veland, N., Kim, J., Chen, T., Sudol, M., Walker, C., and Bedford, M. T. (2017) PRMT5 C-terminal Phosphorylation Modulates a 14-3-3/PDZ Interaction Switch, J. Biol. Chem 292, 2255-2265. (18) Chi, C. N., Bach, A., Stromgaard, K., Gianni, S., and Jemth, P. (2012) Ligand binding by PDZ domains, Biofactors 38, 338-348. (19) Sundell, N. G., Arnold, R., Ali, M., Orts, J., Guentert, P., Chi, N. C., and Ivarsson, Y. (2017) Proteome-wide analysis of phospho-regulated PDZ domain interactions through phosphomimetic proteomic peptide phage display, Biorxiv doi.org/10.1101/211250. (20) Pangon, L., Van Kralingen, C., Abas, M., Daly, R. J., Musgrove, E. A., and KohonenCorish, M. R. J. (2012) The PDZ-binding motif of MCC is phosphorylated at position-1 and controls lamellipodia formation in colon epithelial cells, Bba-Mol. Cell. Res. 1823, 1058-1067. (21) Clairfeuille, T., Mas, C., Chan, A. S., Yang, Z., Tello-Lafoz, M., Chandra, M., Widagdo, J., Kerr, M. C., Paul, B., Merida, I., Teasdale, R. D., Pavlos, N. J., Anggono, V., and Collins, B. M. (2016) A molecular code for endosomal recycling of phosphorylated cargos by the SNX27-retromer complex, Nat. Struct. Mol. Biol. 23, 921-932. (22) Vogeli, B., Bibow, S., and Chi, C. N. (2016) Enzyme Selectivity Fine-Tuned through Dynamic Control of a Loop, Angew. Chem. Int. Ed. Engl. 55, 3096-3100. (23) Takahashi, N., Hayano, T., and Suzuki, M. (1989) Peptidyl-prolyl cis-trans isomerase is the cyclosporin A-binding protein cyclophilin, Nature 337, 473-475. (24) Chi, C. N., Vogeli, B., Bibow, S., Strotz, D., Orts, J., Guntert, P., and Riek, R. (2015) A Structural Ensemble for the Enzyme Cyclophilin Reveals an Orchestrated Mode of Action at Atomic Resolution, Angew. Chem. Int. Ed. Engl. 54, 11657-11661. (25) Fuentes, E. J., Gilmore, S. A., Mauldin, R. V., and Lee, A. L. (2006) Evaluation of energetic and dynamic coupling networks in a PDZ domain protein, J. Mol. Biol. 364, 337-351. (26) Lisi, G. P., and Loria, J. P. (2016) Solution NMR Spectroscopy for the Study of Enzyme Allostery, Chemical reviews 116, 6323-63689.

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chemical shift peturbation

shift sign analysis

binding residues

1

Δ15N shift

15N (ppm)

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0

-1

1H (ppm)

718

758 798 Sequence

829

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